Engineering with Rubber: How to design Rubber Components

rubberchem

一本英文版的橡胶制品设计手册
共有六个压缩卷

. B% V4 ?" P) P  h/ p4 B[ 本帖最后由 rubberchem 于 2007-1-28 12:26 编辑 ]

rubberchem

1. Introduction ........................................................................ 1
, e! O2 r5 Y) L' b1.1 Rubber in Engineering ............................................................ 2
" `7 E- E% Z( v/ l1.2 Elastomers .............................................................................. 2
7 ~8 P, H& l# g2 s1.3 Dynamic Application ................................................................ 3
9 D3 ?7 f# d( @1.4 General Design Principles ...................................................... 4
1.5 Thermal Expansivity, Pressure, and Swelling ........................ 4
( x% }( Q/ p/ u0 d4 x, N1.6 Specific Applications and Operating Principles ...................... 5
1.7 Seal Life ................................................................................... 8
1.8 Seal Friction ............................................................................ 8
; p* ^7 U  c5 B8 |" K  m1.9 Acknowledgments ................................................................... 8
8 ^) U3 `0 m$ Z" ?& ~# E1.10 References .............................................................................. 9
4 T: N8 k& t7 P$ o* p2. Materials and Compounds ................................................ 11
2.1 Introduction .............................................................................. 13
! B4 @' `2 v: ^* A" g% V* E2.2 Elastomer Types ..................................................................... 13
( s  j, X  R. T2 [( [- p' I% Y2.2.1 General-Purpose Elastomers ................................. 13
2.2.1.1 Styrene-Butadiene Rubber (SBR) ............. 13
" j+ x% Z7 o( d" @( p5 Y) G2.2.1.2 Polyisoprene (NR, IR) ............................... 14
2.2.1.3 Polybutadiene (BR) ................................... 15
6 a; w- \9 g" i! L# G# i- i2.2.2 Specialty Elastomers ............................................. 15
2.2.2.1 Polychloroprene (CR) ................................ 15
2.2.2.2 Acrylonitrile-Butadiene Rubber
/ `: E  k4 ~8 }% s(NBR) ........................................................ 16
  ?) Y+ s4 G7 J% f. u! O. F2.2.2.3 Hydrogenated Nitrile Rubber
& B& F( z7 n" K+ h: `+ d( J0 t(HNBR) ...................................................... 16
: {2 w* n+ R( ~3 v# p' m2.2.2.4 Butyl Rubber (IIR) ..................................... 16
5 X9 S$ Q' s- ~2 j: @- A% i8 W% R2.2.2.5 Ethylene-Propylene Rubber
4 d  M( |" B" O# h! T(EPR, EPDM) ............................................ 16
6 F5 J4 L/ }* K) f3 @2.2.2.6 Silicone Rubber (MQ) ................................ 17
* K% C7 {! \3 ^& m" c9 x- o2.2.2.7 Polysulfide Rubber (T) .............................. 17
2.2.2.8 Chlorosulfonated Polyethylene
" e' l0 L) X7 j0 O(CSM) ........................................................ 17
' r$ Y& |  p' R5 `9 ^) D* U( w/ P2.2.2.9 Chlorinated Polyethylene (CM) ................. 17
- W+ Y) p. R1 A0 W1 A2.2.2.10 Ethylene-Methyl Acrylate Rubber
(AEM) ........................................................ 18
( P. l- |* n, ^" f# h2.2.2.11 Acrylic Rubber (ACM) ............................... 18
  }- G  K6 X1 t7 A) i8 @2.2.2.12 Fluorocarbon Rubbers (FKM) ................... 18
2.2.2.13 Epichlorohydrin Rubber (ECO) ................. 18
- S$ h& j# h6 ?, _' D2.2.2.14 Urethane Rubber ....................................... 18
2.3 Compounding .......................................................................... 19
4 U9 @( a9 b9 |; {/ u; z2.3.1 Vulcanization and Curing ....................................... 19
2.3.1.1 Sulfur Curing ............................................. 19
2.3.1.2 Determination of Crosslink Density ........... 21
( z8 V* c, j5 z- q2.3.1.3 Influence of Crosslink Density ................... 22
2.3.1.4 Other Cure Systems .................................. 23
* t" c. y4 _- d7 `& p: y( z7 ~$ ~# B2.3.2 Reinforcement ....................................................... 23
2.3.3 Anti-Degradants ..................................................... 25
2.3.3.1 Ozone Attack ............................................. 25
3 s: {9 w& X7 L( N6 b  k! n( B2.3.3.2 Oxidation ................................................... 26
" ]' A  o( B/ C  u2.3.4 Process Aids .......................................................... 28
2.3.5 Extenders .............................................................. 28
2.3.6 Tackifiers ............................................................... 29
2.4 Typical Rubber Compounds ................................................... 29

rubberchem

Acknowledgments ............................................................................ 33
Bibliography ...................................................................................... 33
Problems .......................................................................................... 34
Answers ............................................................................................ 34
/ e6 i* q/ ?. p/ A3. Elasticity ............................................................................. 35
5 F8 `. _) z  C: Q, s: p8 z; {3.1 Introduction .............................................................................. 37
0 W7 A, C/ H2 d5 o2 G/ R3.2 Elastic Properties at Small Strains .......................................... 37
3.2.1 Elastic Constants ................................................... 37
3.2.2 Relation between Shear Modulus G and
Composition ........................................................... 40
5 g1 x* |  Y9 E/ }! p) P& L3.2.3 Stiffness of Components ........................................ 42
3.2.3.1 Choice of Shear Modulus .......................... 42
/ ?$ F( {) Q8 L5 B8 V. {# h3.2.3.2 Shear Deformation of Bonded Blocks
! n1 n/ M  j# Hand Hollow Cylindrical Tubes .................... 42
3.2.3.3 Small Compressions or Extensions of
2 f! {7 l9 Y4 x4 ?1 ~/ c( VBonded Blocks .......................................... 44
! l! V4 U& H$ f" X3.2.3.4 Maximum Permitted Loads in
! Z8 B: _( A6 j. u# j/ ?" ATension and Compression ........................ 46
3.2.3.5 Indentation of Rubber Blocks by Rigid
: T- p5 J+ x8 D6 ]" l! C% oIndentors ................................................... 47
: i3 `8 z" J  n0 ^: j6 V3.2.3.6 Protrusion of Rubber Through a Hole
in a Rigid Plate .......................................... 49
3.3 Large Deformations ................................................................. 50
3.3.1 General Theory of Large Elastic
Deformations ......................................................... 50
3.3.2 Stress-Strain Relations in Selected Cases ............. 51
7 d9 m# h( l+ p3.3.2.1 General Relations between Stress
' f5 m* F2 ?- u, d7 J7 c5 Cand Strain .................................................. 51
3.3.2.2 Simple Extension ...................................... 51
) C' `5 X) E, N# Y" F3.3.2.3 Evaluation of the Strain Energy
; Q( V1 k- p+ H! \* vFunction W ................................................ 52
1 e3 r% O+ H3 I3.3.2.4 Elastic Behavior of Filled Rubber
2 ~' F7 L! y3 Y% m) v* xVulcanizates .............................................. 54
8 B, h( T0 L4 m% W9 W5 O/ C" Z3.3.2.5 Equi-Biaxial Stretching .............................. 56
3.3.2.6 Constrained Tension (Pure Shear) ........... 57
3.3.2.7 Inflation of a Spherical Shell
(Balloon) .................................................... 58
3.3.2.8 Inflation of a Spherical Cavity .................... 59
3.3.3 Second-Order Stresses ......................................... 60
! T  v4 S( I1 F- ^9 K/ _7 ^3.3.3.1 Simple Shear ............................................. 60
7 T+ m, n, s  J7 q+ d3.3.3.2 Torsion ...................................................... 62
3.4 Molecular Theory of Rubber Elasticity .................................... 63
: z6 k0 B3 p( \4 V3.4.1 Elastic Behavior of a Single Molecular
Strand .................................................................... 63
3.4.2 Elasticity of a Molecular Network ........................... 64
3.4.3 Effective Density of Network Strands ..................... 66
. h0 X6 o7 s0 ?0 O: ?& ~8 f3.4.4 The Second Term in the Strain Energy
) n) [; a( h; c9 N' S. UFunction ................................................................. 66
3.4.5 Concluding Remarks on Molecular Theories .......... 68
Acknowledgments ............................................................................ 68
References ....................................................................................... 68
/ o0 C  m, ]7 B" LProblems .......................................................................................... 70
! @: ^/ }3 z1 N3 J7 XAnswers to Selected Problems ........................................................ 70
$ \: j( p; y# `9 E4. Dynamic Mechanical Properties ....................................... 73
4.1 Introduction .............................................................................. 74
# @: T8 {2 {4 g0 X8 F* F3 c% k4.2 Viscoelasticity .......................................................................... 74
/ ]& z! t; {/ i* e! o0 F4.3 Dynamic Experiments ............................................................. 78
; `1 R' a7 N9 D. f  n+ {1 U4.4 Energy Considerations ............................................................ 82
4.5 Motion of a Suspended Mass ................................................. 82
4.6 Experimental Techniques ....................................................... 87
# _( v8 E* j  B! o& X7 h$ r; F4.6.1 Forced Nonresonance Vibration ............................ 87

rubberchem

4.6.2 Forced Resonance Vibration ................................. 87
4.6.3 Free Vibration Methods ......................................... 87
. z( I& k3 M9 g4 U2 A/ ^4.6.4 Rebound Resilience ............................................... 87
4.6.5 Effect of Static and Dynamic Strain Levels ............ 88
! B2 m8 ?- U" T" j/ k: q; a4.7 Application of Dynamic Mechanical Measurements ............... 89
7 c" h& g& u: I, |& |! l! b4.7.1 Heat Generation in Rubber Components ............... 89
0 P! h( @# `" z9 R7 Y! f( M% D4.7.2 Vibration Isolation .................................................. 89
4.7.3 Shock Absorbers ................................................... 90
6 \$ X: ], X5 X  Y' k, Y) \4.8 Effects of Temperature and Frequency .................................. 90
7 D8 w9 H! Z* W: Y* {# f4.9 Thixotropic Effects in Filled Rubber Compounds ................... 94
- g% V0 i7 P, B3 L& O0 h( b3 v2 Q, u% UAcknowledgements .......................................................................... 94
References ....................................................................................... 96
! V: w9 `, M- I' s, XProblems .......................................................................................... 96
. w* g! \7 z# j2 ?% m6 t; ^5 sAnswers ............................................................................................ 97
2 d4 N, n0 |$ n. H5. Strength .............................................................................. 99
5.1 Introduction .............................................................................. 100
5.2 Fracture Mechanics ................................................................. 100
5.2.1 Analysis of the Test Pieces .................................... 102
5.2.2 The Strain Energy Concentration at a
. ]* Y3 k, I5 g/ U! GCrack Tip ............................................................... 103
5.3 Tear Behavior .......................................................................... 104
6 t* ], @$ w( m& m1 ~5 \& y& [* C5.4 Crack Growth under Repeated Loading ................................. 109
7 I) U+ g3 [6 x% a) m& E5.4.1 The Fatigue Limit and the Effect of Ozone ............. 111
& [3 Q& L" @& H; H; @5.4.2 Physical Interpretation of G0 .................................. 113
4 M7 s4 W/ f3 ^$ h5.4.3 Effects of Type of Elastomer and Filler .................. 114
5.4.4 Effect of Oxygen .................................................... 114
5.4.5 Effects of Frequency and Temperature .................. 116
7 m6 T. U2 E9 `+ Z- [, N5.4.6 Nonrelaxing Effects ................................................ 116
5.4.7 Time-Dependent Failure ........................................ 117
, |+ N! t; N1 r( K% n5.5 Ozone Attack ........................................................................... 117
5.6 Tensile Strength ...................................................................... 121
5.7 Crack Growth in Shear and Compression .............................. 122
5.8 Cavitation and Related Failures .............................................. 125
9 C) o+ l% N. e2 ?( Z5.9 Conclusions ............................................................................. 126
Bibliography ...................................................................................... 126
, Q% `7 z5 S4 W) X/ _6 QProblems .......................................................................................... 129
Answers ............................................................................................ 131
6. Mechanical Fatigue ............................................................ 137
$ r9 i- \* a) c; D& U2 f6.1 Introduction .............................................................................. 139
' `0 j  `& j' |6.2 Application of Fracture Mechanics to Mechanical
, L% }( L7 {" ^# V/ p* vFatigue of Rubber ................................................................... 140
1 S7 N8 y0 x& S6.3 Initiation and Propagation of Cracks ....................................... 142
6.3.1 Fatigue Crack Initiation .......................................... 142
6.3.2 Fatigue Life and Crack Growth .............................. 143
# a: [& z4 ^) r7 ~7 e6.3.3 Fatigue Crack Propagation: The Fatigue
Crack Growth Characteristic .................................. 144
% ^1 ?' D8 [% v( d7 O* o6.3.4 Fatigue Life Determinations from the Crack
Growth Characteristics .......................................... 146
- H5 @4 K2 F% W8 _, r6.4 Fatigue Crack Growth Test Methodology ............................... 148
6.4.1 Experimental Determination of Dynamic
Tearing Energies for Fatigue Crack
+ E% |, i  l7 F. ~. _6 X: n2 y: V# DPropagation ........................................................... 148
6.4.2 Kinetics of Crack Growth ....................................... 149
6.4.3 Effects of Test Variables on Fatigue Crack
  Z: s& r' `3 S* C+ l( R+ KGrowth Characteristics and Dynamic
( ~7 D3 K$ N3 CFatigue Life ............................................................ 150
6.4.3.1 Waveform .................................................. 150
6.4.3.2 Frequency ................................................. 150
( a$ s; A0 _# X! N- Z6.4.3.3 Temperature .............................................. 150

rubberchem

6.4.3.4 Static Strain/Stress .................................... 152
6.5 Material Variables and Their Effect on Fatigue Crack
/ ]& j; {9 s  j" ~* XGrowth ..................................................................................... 154
6.5.1 Reinforcing Fillers and Compound Modulus ........... 154
# n. o, ~2 w5 N" c! y3 F- c6.5.2 Elastomer Type ..................................................... 156
6.5.3 Vulcanizing System ............................................... 157
6.6 Fatigue and Crack Growth of Rubber under Biaxial
) V3 ?/ l7 Z9 i* ?. fStresses .................................................................................. 158
% |8 n& v7 ?3 B% ~, Y6.7 Fatigue in Rubber Composites ............................................... 159
% O5 [# I+ K. G5 ^# d0 f: O" J6.7.1 Effect of Wires, Cords, and Their Spacing on
Fatigue Crack Propagation .................................... 160
- s( Q) T% d3 L. R- v6.7.2 Effect of Minimum Strain or Stress ......................... 160
6.7.3 Comparison of S-N Curve and Fatigue Crack
7 L3 _2 u5 v+ ?1 r( wPropagation Constants for Rubber-Wire
Composites ............................................................ 163
6.7.4 Fatigue of Two-Ply Rubber-Cord Laminates .......... 164
# w5 E5 P4 A2 o" |7 {( d6.8 Fatigue Cracking of Rubber in Compression and Shear
Applications ............................................................................. 165
6.8.1 Crack Growth in Compression ............................... 165
3 S, x) I$ E% w/ u3 {$ r6.8.2 Crack Growth in Shear .......................................... 167
6.9 Environmental Effects ............................................................. 168
6.10 Modeling and Life Predictions of Elastomeric
Components ............................................................................ 169
6.11 Fatigue Crack Propagation in Thermoplastic
& A, J/ q6 ?; {/ c; aElastomers .............................................................................. 170
6.12 Durability of Thermoplastic Elastomers .................................. 170
0 d* h+ L$ o! H6.13 Summary ................................................................................. 172
Acknowledgments ............................................................................ 173
References ....................................................................................... 173
Problems .......................................................................................... 174
0 ^; y; e3 d7 @7 X* C, F. Z3 gAnswers ............................................................................................ 175
7. Durability ............................................................................ 177
0 \) S5 M  q+ i5 w$ i2 b% Q3 B- @& K7.1 Introduction .............................................................................. 179
7.2 Creep, Stress Relaxation, and Set ......................................... 180
) d. j2 N" X8 i; u, _7.2.1 Creep ..................................................................... 181
% \( j7 j6 a; `6 p; ~7.2.2 Stress Relaxation .................................................. 181
! I$ g% Z! I  b" V, z7.2.3 Physical Relaxation ............................................... 182
; `% m# m* [# G/ H; v+ d3 d+ k2 X7.2.4 Chemical Relaxation .............................................. 183
. h2 e, x1 \8 i) D7 u7.2.5 Compression Set and Recovery ............................ 184
* L' [$ W( _$ j' H# v8 @- z7.2.6 Case Study ............................................................ 185
7.3 Longevity of Elastomers in Air ................................................ 186
# Y7 ]9 J$ |3 f( ^" X* p7.3.1 Durability at Ambient Temperatures ....................... 186
7.3.2 Sunlight and Weathering ....................................... 186
7.3.3 Ozone Cracking ..................................................... 187
7.3.4 Structural Bearings: Case Studies ......................... 187
0 I7 i) O& S2 F  R7.3.4.1 Natural Rubber Pads on a Rail
0 r2 U0 R' k- T0 X. V& wViaduct after 100 Years of Service ............ 187
' X8 U5 z& Q  g5 N, k4 y6 `7.3.4.2 Laminated Bridge Bearings after 20
4 \, }; r6 x+ {, _6 ^) L5 S' c5 G8 }6 EYears of Service ........................................ 189
7.4 Effect of Low Temperatures .................................................... 192
7.4.1 Glass Transition ..................................................... 192
7.4.2 Crystallization ........................................................ 192
# ?1 Y8 g* }8 D) ]) z7.4.3 Reversibility of Low Temperature Effects ............... 193
7.5 Effect of Elevated Temperatures ............................................ 193
7.6 Effect of Fluid Environments ................................................... 195
- Y/ W# O( _. a3 U$ t7 y( d! Q7.6.1 Aqueous Liquids .................................................... 199
7.6.2 Hydrocarbon Liquids .............................................. 201
7.6.3 Hydrocarbon and Other Gases .............................. 203
3 ~/ ]  G" E2 ^& C" M7 |, b7.6.4 Effects of Temperature and Chemical
! y. b2 x/ n! r8 b4 q' u; z9 |Attack .................................................................... 207
7.6.5 Effect of Radiation ................................................. 209

rubberchem

7.7 Durability of Rubber-Metal Bonds ........................................... 209
7.7.1 Adhesion Tests ...................................................... 210
7.7.2 Rubber-Metal Adhesive Systems ........................... 211
7.7.3 Durability in Salt Water: Role of
Electrochemical Potentials ..................................... 212
7.8 Life Prediction Methodology .................................................... 214
+ i- P: r& M0 c: g& N5 rAcknowledgement ............................................................................ 217
References ....................................................................................... 217
Problems .......................................................................................... 218
& o( \, D* q2 Y: a* KAnswers ............................................................................................ 220
8. Design of Components ..................................................... 223
8.1 Introduction .............................................................................. 224
8 r! C2 U0 ?- Y. a8.2 Shear and Compression Bearings .......................................... 226
! z$ q; f: }1 q: p9 x, m8.2.1 Planar Sandwich Forms ......................................... 226
8.2.1.1 Problem ..................................................... 230
" X6 q9 U: M4 T* X8.2.2 Laminate Bearings ................................................. 231
: p2 s! A6 S) s0 A* O' \9 O8.2.2.1 Problem ..................................................... 231
8 S6 p+ a/ @# ^/ u6 \" X8.2.3 Tube Form Bearings and Mountings ...................... 233
8.2.3.1 Problem ..................................................... 233
' c' G0 q! V+ n2 D% k8.2.3.2 Problem ..................................................... 236
% e3 g* [+ n3 ~) J8.2.4 Effective Shape Factors ......................................... 237
7 c. ?; ^: v/ w5 P8.3 Vibration and Noise Control .................................................... 238
3 Q! b. x/ Y1 G( w* S8.3.1 Vibration Background Information .......................... 239
8.3.2 Design Requirements ............................................ 241
2 F# O5 b3 e9 ]' X8.3.3 Sample Problems .................................................. 241
2 W# N. B+ ?% Q& U5 h8.3.3.1 Problem ..................................................... 241
8.3.3.2 Problem ..................................................... 245
8.3.3.3 Problem ..................................................... 246
4 v9 W. @7 q: d( }1 s7 u  F8.4 Practical Design Guidelines .................................................... 249
8.5 Summary and Acknowledgments ........................................... 250
2 j( T  d4 e) [$ p' mNomenclature ................................................................................... 251
References ....................................................................................... 251
# \2 r9 z# P  Q9 h3 j0 d# d) R+ JProblems for Chapter 8 .................................................................... 252
Solutions for Problems for Chapter 8 ............................................... 253
9. Finite Element Analysis .................................................... 257
" _1 `/ \0 J! g, p9.1 Introduction .............................................................................. 259
+ j% t8 X3 M) ?7 n8 `4 u9.2 Material Specification .............................................................. 260
9.2.1 Metal ..................................................................... 260
9.2.2 Elastomers ............................................................ 260
9.2.2.1 Linear ........................................................ 260
9.2.2.2 Non-Linear ................................................ 265
# A& m* J$ y" Q3 P6 U8 x2 W' ?6 W9.2.3 Elastomer Material Model Correlation .................... 274
9.2.3.1 ASTM 412 Tensile Correlation .................. 274
9.2.3.2 Pure Shear Correlation ............................. 274
9.2.3.3 Bi-Axial Correlation ................................... 275
5 x7 J. i2 O: m* b6 p; q0 @+ R9.2.3.4 Simple Shear Correlation .......................... 276
9.3 Terminology and Verification .................................................. 276
6 R% L7 Y: T) R+ `  S' \3 x/ u6 |5 d9.3.1 Terminology ........................................................... 276
9.3.2 Types of FEA Models ............................................ 277
9.3.3 Model Building ....................................................... 278
/ ~0 [) Q# _9 t3 R' W) _7 ]9.3.3.1 Modeling Hints for Non-Linear FEA .......... 278
: ?" W/ G* T' q0 t1 s9.3.4 Boundary Conditions ............................................. 279
9.3.5 Solution ................................................................. 280
# b4 H( j( {4 l( z9.3.5.1 Tangent Stiffness ...................................... 280
9.3.5.2 Newton-Raphson ...................................... 281
) E, Z& w& }& M# B3 {. ~% B9.3.5.3 Non-Linear Material Behavior ................... 281
: |- Y: b+ E. S& C6 s9.3.5.4 Visco-Elasticity (See Chapter 4) ............... 281
9.3.5.5 Model Verification ...................................... 282
' k+ [2 M3 u& p9 e0 R1 i+ P/ v9.3.6 Results .................................................................. 282
8 m  \% p6 I: o# w9.3.7 Linear Verification .................................................. 283
( Y( O8 o6 m' n% P, ?9.3.8 Classical Verification – Non-Linear ........................ 283
9.4 Example Applications .............................................................. 287
- u7 }; g4 W: |, s9.4.1 Positive Drive Timing Belt ...................................... 287
, c( d& b4 i0 N/ p) Y3 X& M7 S$ [- t9.4.2 Dock Fender .......................................................... 288
) r7 N* @' r. c+ P+ ]9.4.3 Rubber Boot .......................................................... 289
9.4.4 Bumper Design ...................................................... 291
9.4.5 Laminated Bearing ................................................. 293
" r3 k' _. v0 F; E; \9.4.6 Down Hole Packer ................................................. 297
9.4.7 Bonded Sandwich Mount ....................................... 297
4 o4 c8 y# [* J' Y  o% {# k9.4.8 O-Ring ................................................................... 299
# I- H. i$ h: Q9.4.9 Elastomer Hose Model .......................................... 301
" s& d! a1 P! V/ _: q9.4.10 Sample Belt ........................................................... 301
* I$ O1 k4 f- F$ x9 \+ d1 C$ I  AReferences ....................................................................................... 304
* X+ u7 v& K8 |( }1 `10. Tests and Specifications ................................................... 307
0 T$ K5 ]& g1 S* O10.1 Introduction .............................................................................. 309
10.1.1 Standard Test Methods ......................................... 309
10.1.2 Purpose of Testing ................................................. 309
10.1.3 Test Piece Preparation .......................................... 310
# s; l, G. q$ x; `# Z% Q% k10.1.4 Time between Vulcanization and Testing ............... 310
10.1.5 Scope of This Chapter ........................................... 310
10.2 Measurement of Design Parameters ...................................... 311
10.2.1 Young’s Modulus ................................................... 311
; {$ U$ h) G! ]3 t4 n10.2.2 Shear Modulus ...................................................... 313
7 V  \4 y1 X4 q% ^+ M: [10.2.3 Creep and Stress Relaxation ................................. 315
10.2.3.1 Creep ........................................................ 316
# c# U! D, ~& Q4 p! Z10.2.3.2 Stress Relaxation ...................................... 316